TY - GEN
T1 - Kinematics Modeling and Simulation Analysis of Human Upper Limbs for Rod Lifting
AU - Ji, Yuanzhe
AU - Liu, Yali
AU - Song, Qiuzhi
N1 - Publisher Copyright:
© 2023 ACM.
PY - 2023/10/20
Y1 - 2023/10/20
N2 - With the development of technology, exoskeleton robots have wide application in industrialization and civilian. The purpose of this paper is to analyze the kinematics and kinetics during rod lifting, thus providing the necessary suggestion for power grid maintenance exoskeleton design. Firstly, the human motion data was collected through the 3D motion capture system. Secondly, this article proposed an improved four degrees of freedom model for human pole lifting based on DH (Denavit-Hartenberg) method and human anatomy. Thirdly, we conducted dynamic analysis on the pole lifting motion based on the model and in Opensim software. During the pole hanging stage, the maximum torque of the shoulder joint was 27.7N, and the maximum torque of the elbow joint was 28.3N based on the model, with error rates(the ratio of the error between the calculated value and the simulated value to the calculated value) of 11.5% and 2.8% referring to the data in Opensim simulation. During the pole hanging stage, the maximum torque of the shoulder joint was 36.2N, and the maximum torque of the elbow joint was 16.3N, with error rates of 7.5% and 6.7%. Due to the fact that the source of joint torque is muscle force, we further analyzed muscle strength. The results indicated that we can assist with BRA (brachialis) and INFSP (infraspinatus) during the pole lifting stage, and BIClong (biceps brachii, long head) and INFSP (infraspinatus) during the pole hanging phase. This study provides a theoretical basis for the design of structure and control strategy of upper limb exoskeleton.
AB - With the development of technology, exoskeleton robots have wide application in industrialization and civilian. The purpose of this paper is to analyze the kinematics and kinetics during rod lifting, thus providing the necessary suggestion for power grid maintenance exoskeleton design. Firstly, the human motion data was collected through the 3D motion capture system. Secondly, this article proposed an improved four degrees of freedom model for human pole lifting based on DH (Denavit-Hartenberg) method and human anatomy. Thirdly, we conducted dynamic analysis on the pole lifting motion based on the model and in Opensim software. During the pole hanging stage, the maximum torque of the shoulder joint was 27.7N, and the maximum torque of the elbow joint was 28.3N based on the model, with error rates(the ratio of the error between the calculated value and the simulated value to the calculated value) of 11.5% and 2.8% referring to the data in Opensim simulation. During the pole hanging stage, the maximum torque of the shoulder joint was 36.2N, and the maximum torque of the elbow joint was 16.3N, with error rates of 7.5% and 6.7%. Due to the fact that the source of joint torque is muscle force, we further analyzed muscle strength. The results indicated that we can assist with BRA (brachialis) and INFSP (infraspinatus) during the pole lifting stage, and BIClong (biceps brachii, long head) and INFSP (infraspinatus) during the pole hanging phase. This study provides a theoretical basis for the design of structure and control strategy of upper limb exoskeleton.
KW - human simulation
KW - kinematical modeling
KW - multi-rigid body dynamics
UR - http://www.scopus.com/inward/record.url?scp=85204041077&partnerID=8YFLogxK
U2 - 10.1145/3647817.3647824
DO - 10.1145/3647817.3647824
M3 - Conference contribution
AN - SCOPUS:85204041077
T3 - ACM International Conference Proceeding Series
SP - 45
EP - 51
BT - Proceedings of 2023 12th International Conference on Bioinformatics and Biomedical Science, ICBBS 2023
PB - Association for Computing Machinery
T2 - 12th International Conference on Bioinformatics and Biomedical Science, ICBBS 2023
Y2 - 20 October 2023 through 22 October 2023
ER -